Germanium MOS: An Evaluation from Carrier Quantization and Tunneling Current

Tony Low; Y. T. Hou; M. F. Li; Chunxiang Zhu; D. L. Kwong; Albert Chin

doi:10.1109/VLSIT.2003.1221113

Germanium MOS: An Evaluation from Carrier Quantization and Tunneling Current

Tony Low^*, Y. T. Hou, M. F. Li, Chunxiang Zhu, D. L. Kwong, Albert Chin

^*Corresponding author for this work

Research output: Contribution to journal › Conference article › peer-review

15 Scopus citations

Abstract

Ge is promising as an alternative channel material due to its high carrier mobility. In this work, we report an evaluation of Ge MOS from quantization and gate tunneling current simulations. Key findings are: (1) Electron quantization effect is stronger and thus more important in Ge than in Si, and results in smaller inversion capacitance in NMOS. (2) Using constant inversion charge for supply voltage V_DD scaling, moderate reduction in inversion charge is required to meet ITRS roadmap, which can be achieved with high mobility channel. (3) Due to its smaller electron mass and resulting higher electron quantization energy, Ge MOS shows considerably larger gate tunneling current than Si MOS for the same gate dielectric. (4) High-K gate dielectrics are required for low leakage; however, significant challenges exist in the formation of high quality interface layer between high-K and Ge.

Original language	English
Pages (from-to)	117-118
Number of pages	2
Journal	Digest of Technical Papers - Symposium on VLSI Technology
DOIs	https://doi.org/10.1109/VLSIT.2003.1221113
State	Published - 1 Oct 2003
Event	2003 Symposium on VLSI Technology - Kyoto, Japan Duration: 10 Jun 2003 → 12 Jun 2003

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title = "Germanium MOS: An Evaluation from Carrier Quantization and Tunneling Current",

abstract = "Ge is promising as an alternative channel material due to its high carrier mobility. In this work, we report an evaluation of Ge MOS from quantization and gate tunneling current simulations. Key findings are: (1) Electron quantization effect is stronger and thus more important in Ge than in Si, and results in smaller inversion capacitance in NMOS. (2) Using constant inversion charge for supply voltage VDD scaling, moderate reduction in inversion charge is required to meet ITRS roadmap, which can be achieved with high mobility channel. (3) Due to its smaller electron mass and resulting higher electron quantization energy, Ge MOS shows considerably larger gate tunneling current than Si MOS for the same gate dielectric. (4) High-K gate dielectrics are required for low leakage; however, significant challenges exist in the formation of high quality interface layer between high-K and Ge.",

author = "Tony Low and Hou, {Y. T.} and Li, {M. F.} and Chunxiang Zhu and Kwong, {D. L.} and Albert Chin",

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language = "English",

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journal = "Digest of Technical Papers - Symposium on VLSI Technology",

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note = "2003 Symposium on VLSI Technology ; Conference date: 10-06-2003 Through 12-06-2003",

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TY - JOUR

T1 - Germanium MOS

T2 - 2003 Symposium on VLSI Technology

AU - Low, Tony

AU - Hou, Y. T.

AU - Li, M. F.

AU - Zhu, Chunxiang

AU - Kwong, D. L.

AU - Chin, Albert

PY - 2003/10/1

Y1 - 2003/10/1

N2 - Ge is promising as an alternative channel material due to its high carrier mobility. In this work, we report an evaluation of Ge MOS from quantization and gate tunneling current simulations. Key findings are: (1) Electron quantization effect is stronger and thus more important in Ge than in Si, and results in smaller inversion capacitance in NMOS. (2) Using constant inversion charge for supply voltage VDD scaling, moderate reduction in inversion charge is required to meet ITRS roadmap, which can be achieved with high mobility channel. (3) Due to its smaller electron mass and resulting higher electron quantization energy, Ge MOS shows considerably larger gate tunneling current than Si MOS for the same gate dielectric. (4) High-K gate dielectrics are required for low leakage; however, significant challenges exist in the formation of high quality interface layer between high-K and Ge.

AB - Ge is promising as an alternative channel material due to its high carrier mobility. In this work, we report an evaluation of Ge MOS from quantization and gate tunneling current simulations. Key findings are: (1) Electron quantization effect is stronger and thus more important in Ge than in Si, and results in smaller inversion capacitance in NMOS. (2) Using constant inversion charge for supply voltage VDD scaling, moderate reduction in inversion charge is required to meet ITRS roadmap, which can be achieved with high mobility channel. (3) Due to its smaller electron mass and resulting higher electron quantization energy, Ge MOS shows considerably larger gate tunneling current than Si MOS for the same gate dielectric. (4) High-K gate dielectrics are required for low leakage; however, significant challenges exist in the formation of high quality interface layer between high-K and Ge.

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DO - 10.1109/VLSIT.2003.1221113

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SN - 0743-1562

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JO - Digest of Technical Papers - Symposium on VLSI Technology

JF - Digest of Technical Papers - Symposium on VLSI Technology

Y2 - 10 June 2003 through 12 June 2003

ER -

Germanium MOS: An Evaluation from Carrier Quantization and Tunneling Current

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